JPS62194870A - Therapy apparatus by laser beam - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention is a device that detects a treatment point with a laser beam and stimulates the treatment point with a therapeutic laser beam to treat a disease.

In general, the living body becomes fatigued due to excessive exercise, or
Treatment methods for abnormalities in internal organs are broadly divided into those based on Western medicine and those based on Oriental medicine.

However, in recent years, various treatments based on the latter, oriental medicine, have become popular, and so-called tension, moxibustion, acupressure, etc. are widely known as representative treatments, and these treatments are currently , is attracting attention worldwide.

By the way, when performing the above treatment, so-called acupuncture points [
You can perform acupuncture, moxibustion, and acupressure focusing on the acupuncture point, that is, the treatment point, or use various low-frequency treatment Be devices that have been actively developed in recent years to apply electrical stimulation to the living body. Treatments that add stimulation are being carried out, but it is first necessary to find the acupuncture points.

The present applicant has proposed Japanese Patent Publication No. 60-40297 as a treatment point detection device for treatment based on Oriental medicine.

The present invention relates to the above-mentioned treatment point detection technology [Patent Publication No. 60-4029]
In addition to 73, this method aims to improve the therapeutic effect by irradiating the detected treatment point with laser light to stimulate it.

By the way, the method of applying acupuncture and moxibustion to treatment points (acupuncture points, pressure points) has been practiced in China and Japan since ancient times, and in recent years it has been intensively researched and put into practical use in countries such as the Soviet Union, Eastern Europe, France, and Germany. ing. However, the pain and strong tingling sensation of acupuncture, and the intense heat and traces of moxibustion pose major obstacles, and the reality is that it is not widely used despite its therapeutic effects.

Meanwhile, around 1970, a research group led by Iniushin Nikiov of the Soviet Union began using He-N instead of acupuncture.
Using e-laser light, we conducted systematic experimental research and confirmed that laser light has local vasodilation, analgesic, and anti-inflammatory effects, causing a huge stir in the medical world.

Also, according to animal experiments at the Faculty of Veterinary Medicine, Northeastern Agricultural University, He
- After irradiating the treatment points (acupuncture points) with Ne laser light, there was an increase in the pain level of the animal, and at the same time 0p after stimulation with laser light.
It was confirmed that injecting the Ioid antagonist No1Oxone had a strong antagonizing effect on the laser effect, and this showed that the analgesic effect produced by irradiating the treatment point with laser light was similar to acupuncture stimulation, and that Endrphin stimulates the brain. The report states that it is thought to have been released into the fluid and pituitary gland.

In 1978, laser beams were proven to be painless and effective in place of acupuncture in Germany, and were commercialized for the first time through joint research and development between the West German Aerospace Research Group and Siemens AG.

Furthermore, in Japan, research began in various places around 1980, and the results of the research have been announced by many groups, including the Society of Laser Medicine.

Nowadays, it is an undeniable fact that stimulation by laser light and heat is effective for treatment, mainly by stimulating the subcutaneous area from 3 tm to 15 ta under the skin, although it varies depending on the wavelength [laser beam used]. In reality, new treatment devices are being developed.

Fortune telling.

The above-mentioned effective laser beam is expected to be most effective when stimulated to an effective location (treatment point), and the present invention combines it with the treatment point detection device proposed by the applicant. The present invention provides a device that automatically and appropriately irradiates a treatment point with laser light to treat a disease.

One aspect of the present invention is a treatment point detection device that irradiates and travels a laser beam onto a living body and detects a point where the reflectance of the reflected laser beam changes, and a treatment point detection device that detects the treatment point detected by the treatment point detection device. It consists of a treatment device that automatically stimulates the treatment point by irradiating and running a treatment laser beam on the treatment point, and a laser beam with a mid-infrared wavelength is used to detect the treatment point, and the treatment device This is a device that effectively treats a treatment point using a laser beam with a wavelength that has the ability to transport 3 mm to 15 mm subcutaneously.

The treatment point is detected by irradiating and traveling the treatment point detection laser light on the living body, storing and displaying the detected data, and then driving and controlling the treatment device according to the stored data to detect the detected treatment point. The point is irradiated with therapeutic laser light.

In the drawing, (1) is the living body that is the subject to be treated, and (2) is the scanning system that irradiates and travels the laser beam on the living body (1), which is a synchronized system that operates based on commands from the image processing device (3). (The drive is controlled by the i generator (4).The image processing device (3)
) is an A/D converter (5) that converts an external analog signal into a digital signal, a microprocessor sensor unit RAM that processes the digital signal, and the R
It consists of an AM and a ROM. (6) is an operation button of the image processing device, and (7), (8), and (9) are a monitor, VTR, and printer for displaying data stored in the image processing device. (10) is a laser beam generator (first
(1)) is a therapeutic laser light generator (second laser light generator), and is driven and controlled by the image processing device (3). (12) is a half mirror provided on the optical axis of the first laser beam generator (10), (
13) is a fixed reflection mirror installed on the optical axis of the second laser beam generator (1)), and (14) is a moving reflection mirror installed on the optical axis of the first laser beam generator (10). It's Mira. (
15) is a photodetector that receives the reflected light from the half mirror (12), and (16) is an amplifier that amplifies the signal from the photodetector and sends it to the A/D converter (5). Note that the laser beam for treatment point detection [first laser beam] has a wavelength of 2.
Mid-infrared laser light from 5μ to 1006μm, e.g. C
An O2 laser beam is used, and the therapeutic laser beam [second laser beam] is a laser beam that has the ability to transport from 3 mm to 15 mm subcutaneously, such as a He-Ne laser beam with a wavelength of 0.633 pm. A 1.06 μm YAG laser beam is used.

However, in the case of special usage, the above does not apply.

Note that the word "light" generally refers to visible light in the range of 0.38 to 0.75 μm, but the word "laser light" used in this specification ranges from visible light to invisible light, and uniformly refers to laser light. It uses eight leaves called light. More precisely, it means laser energy.

In the above device, the first laser beam emitted from the first laser beam generator (10) passes through the half mirror (12), enters the scanning system (2), and irradiates the living body (1),
The reflected light passes through the same scanning system (2) and passes through the half mirror (
12), changes the optical path by 90 degrees and enters the photodetector (15). After this is sent to the next stage amplifier (16) and amplified, it enters the next image processing device (3) and the A/D converter (
In 5) the analog signal is converted into a digital signal. Put this signal into the microprocessor unit RAM,
The signal is visualized as programmed in the ROM memory in the previous stage and sent to the monitor. If necessary, print it out with a printer and convert it to rt542 with a VTR. With the above steps, imaging of biological information is completed. In this case, symptoms and
If multiple treatment points appear due to the size of the scan area selected, or if the strength of the treatment points (the stage is determined by the ROM program), which treatment points should be treated and in what order? There are two main ways to think about whether this is the case.

The first method is to follow the ROM program, for example,
If you program it to stimulate only the strongest treatment point, or to stimulate sequentially from the strongest response treatment point to the weakest response treatment point, it will automatically do that.

The second method is to visually check the treatment points on the monitor, decide which treatment point to select, and stimulate only that point by selecting that point with the pen attached to the monitor. I'm doing it (.

Selection of the first and second methods is performed using operation buttons.

The treatment point detected by the above method is treated with laser light in the following manner.

First, a phalanx signal from the microprocessor unit RAM turns on the second [norther light generator (1)], and the first
The laser light generator (10) is turned off. Then, the second laser beam from the second laser beam generator (1) passes through the fixed reflection mirror (13) and is transferred to the first laser beam by the movable reflection mirror (14).
The laser beam is incident on the optical axis of the laser beam generator (10), and the RAM
The scanning system (2
), guides a light path to the detected treatment point, and irradiates the treatment point.

Note that the objective treatment effect will become clearer if the results before and after treatment are compared using a VTR or printer.

Further, the reflected light receiving method using the tracking method disclosed in the above-mentioned Japanese Patent Publication No. 60-40297, shown in FIG. It is inserted into the detector, and the subsequent processing is the same as in the present invention.

The present invention provides a treatment point detection device that irradiates and travels a laser beam onto a living body and detects a point where the reflectance of the reflected laser beam changes, and a treatment point detection device that detects a point where the reflectance of the reflected laser beam changes. It consists of a treatment device that automatically stimulates the treatment point by irradiating and traveling with a treatment laser beam, and a laser beam with a mid-infrared wavelength is used to detect the treatment point. 6. Since we used a laser beam with a wavelength that has the ability to transport waves from 3u to 15m below the waves, it is reliable and requires special experience6. Finding treatment points is the easiest way. In addition, the treatment point can be printed out or automatically irradiated with laser light to the treatment point automatically based on the detection results of the treatment point. Be able to automatically treat diseases.

[Brief explanation of drawings]

The drawing is a schematic explanatory diagram of a treatment device using laser light according to the present invention. (L) - Biological body, (2> - Scanning system, (3) - Both image processing device, (4) - Synchronization signal generator, (5 Fu - A/D converter, RAM - 11 Microprocessor) 1+-unit, (6
)−・−operation button, (7)−・−・monitor,
(43) ,,-VTR1(9)-Printer, (1
0) - Laser light generator for treatment point detection [first laser light generator], (1)) - Laser light generator for treatment [second laser light generator], (12) - Half mirror, ( 13) -Fixed reflection mirror, (14) -Moving reflection mirror, (15) -Photodetector, (16> -m-Amplifier. Patent applicant Meguro -31-1 -1゜

Claims (1)

[Claims] (1) A treatment point detection device that irradiates and travels a laser beam onto a living body and detects a point where the reflectance of the reflected light of the laser beam changes; It consists of a treatment device that automatically stimulates the treatment point by irradiating and traveling with a laser beam, and uses a mid-infrared wavelength laser beam to detect the treatment point, and also uses a laser beam with a mid-infrared wavelength to detect the treatment point at a depth of 3 mm to 15 mm subcutaneously.
A treatment device using a laser beam, characterized in that it uses a laser beam with a wavelength that has deep penetrating ability.